A surface cleaning head is provided having a casing with a rotatably mounted cleaning brush associated with a brush opening and a drying roller operable in a drying mode. In the drying mode, the drying roller removes water from the rotatably mounted cleaning brush. The surface cleaning head also has a water collection container positioned to receive water removed from the rotatably mounted cleaning brush by the drying roller.

Disclosed are a robot cleaner capable of controlling a water pump of a robot cleaner by a user input through an external control device, a robot cleaning system having the same, and a control method of the robot cleaning system. According to the present invention, user convenience is increased since the amount of water supplied to the mop of the robot cleaner can be controlled according to a cleaning environment, cleaning efficiency is improved by controlling the water pump to quickly wet the mop of the robot cleaner at the beginning of a cleaning operation, and the robot cleaner can be hygienically managed since a user controls the water pump to discharge residual water inside the robot cleaner.

The present invention relates to a robot cleaner, a control system of a robot cleaner and a control method of a robot cleaner, and the invention includes a robot cleaner that stores a map including information on a drivable area of a cleaning area and drives in the cleaning area and a terminal that inputs a cleaning command to the robot cleaner, the terminal setting a virtual designated area on the map in response to a user input, the robot cleaner moving to the designated area and driving within the designated area when the designated area is set from the terminal, and thus, the invention has the effect of intensively cleaning the designated area arbitrarily designated by a user.

Provided is a robot cleaner that travels along a virtual traveling line connecting a start point to a predetermined target point in a straight line. The robot cleaner includes a body having formed therein a space for accommodating a battery, a water container, and a motor, and a pair of rotation plates that have coupled to lower sides thereof, mopping cloths facing a floor surface, and are rotatably disposed on a bottom surface of the body, in which when a shortest distance between the body and the traveling line is greater than or equal to a predetermined reference distance, rotation speeds of the pair of rotation plates are different from each other.

Provided is a robot cleaner that includes a body having formed therein a space for accommodating a battery, a water container, and a motor, a pair of rotation plates that have coupled to lower sides thereof, mopping cloths facing a floor surface, and are rotatably disposed on a bottom surface of the body, and a virtual connection line connecting rotation axes of the pair of rotation plates to each other, in which a midpoint of the connection line moves while drawing a trajectory in a closed curve form on the floor surface in rotary traveling, thereby preventing a center of rotation of the robot cleaner from moving away from an origin of rotation.

Disclosed herein is a robot cleaner. The robot cleaner includes a body, a drive unit provided in the body to power the robot cleaner to travel, and a plurality of rotating members, each rotating about its axis of rotation by the power of the drive unit, a cleaner section being fixable to each of the rotating members to perform wet cleaning on a surface to be cleaned, wherein each of the rotating members has a predetermined angle of tilt and angle of rotation set, so as to determine a traveling direction of the robot cleaner.

The present disclosure relates to a plurality of autonomous mobile robots. A plurality of autonomous mobile robots comprise a first mobile robot including an antenna configured to transmit and receive signals, and a second mobile robot including a first antenna and a second antenna disposed on a front area of a main body thereof to transmit and receive signals to and from the antenna of the first mobile robot. The second mobile robot comprises a control unit configured to determine a relative position of the first mobile robot using the signal received by the first antenna and the second antenna.

A nozzle of a cleaner includes a nozzle body, a rotation cleaning part having a rotation plate to which a rag is attached, a driving device provided in the nozzle body, a water tank, a water supply passage, and a water adjuster of which at least a portion is mounted on the nozzle body at a rear side thereof so as to be exposed to a rear surface or a top surface of the nozzle body. A user standing on the same floor surface as the nozzle body may manipulate the water adjuster by using his or her foot. The water adjuster can adjust an on/off operation and a rotational speed (e.g., rpm) of the pump motor.

A companion animal management apparatus is provided. The companion animal management apparatus includes a main body, a driving module configured to move the main body, and a cleaning module installed in an interior space of the main body and including a part which protrudes out to the front of the main body and retreats back into the main body to process feces inside the main body.

A cleaner including a base defining a suction chamber, a brush roll driven by a brush roll motor, a sensor configured to sense a parameter related to a floor; and a controller having a memory and electronic processor. The controller is configured to receive the parameter, control the brush roll motor based on the parameter and a first floor coefficient, determine a second floor coefficient based on the parameter, and control the brush roll motor based on the second floor coefficient.